Abstract: An augmented reality (AR) system for production-tuning of parameters for a visual tracking robotic picking system. The robotic picking system includes one or more robots configured to pick randomly-placed and randomly-oriented parts off a conveyor belt and place the parts in an available position, either on a second moving conveyor belt or on a stationary device such as a pallet. A visual tracking system identifies position and orientation of the parts on the feed conveyor. The AR system allows picking system tuning parameters including upstream, discard and downstream boundary locations to be visualized and controlled, real-time robot pick/place operations to be viewed with virtual boundaries, and system performance parameters such as part throughput rate and part allocation by robot to be viewed. The AR system also allows virtual parts to be used in simulations, either instead of or in addition to real parts.

Abstract: An augmented reality (AR) system for production-tuning of parameters for a visual tracking robotic picking system. The robotic picking system includes one or more robots configured to pick randomly-placed and randomly-oriented parts off a conveyor belt and place the parts in an available position, either on a second moving conveyor belt or on a stationary device such as a pallet. A visual tracking system identifies position and orientation of the parts on the feed conveyor. The AR system allows picking system tuning parameters including upstream, discard and downstream boundary locations to be visualized and controlled, real-time robot pick/place operations to be viewed with virtual boundaries, and system performance parameters such as part throughput rate and part allocation by robot to be viewed. The AR system also allows virtual parts to be used in simulations, either instead of or in addition to real parts.

Abstract: A method for controlling motion of a robot relative to a conveyor flow direction of a moving conveyor includes the steps of: establishing a tracking frame for coordinating a position and movement of the robot relative to an object support surface of the conveyor; setting an upstream boundary perpendicular or skewed to a conveyor flow direction of the conveyor; setting a downstream boundary perpendicular or skewed to the conveyor flow direction; optionally setting a circular boundary partially overlapping the upstream boundary and the downstream boundary, wherein the upstream boundary, the downstream boundary and the circular boundary are positioned to define a picking area relative to the support surface; and operating the robot to pick objects from the picking area.

Abstract: A method for controlling motion of a robot relative to a conveyor flow direction of a moving conveyor includes the steps of: establishing a tracking frame for coordinating a position and movement of the robot relative to an object support surface of the conveyor; setting an upstream boundary perpendicular or skewed to a conveyor flow direction of the conveyor; setting a downstream boundary perpendicular or skewed to the conveyor flow direction; optionally setting a circular boundary partially overlapping the upstream boundary and the downstream boundary, wherein the upstream boundary, the downstream boundary and the circular boundary are positioned to define a picking area relative to the support surface; and operating the robot to pick objects from the picking area.

Abstract: A method and an apparatus for displaying three-dimensional workcell data includes a hand-held pendant that is provided with 3-D workcell data representing a model of a machine and associated components in a workcell. The hand-held pendant has a display that generates a 3-D visual representation of the workcell data. The pendant can be operated by a user to manipulate the visual representation to change a user viewpoint and to show motion of the machine with associated process information.

Abstract: A robot monitoring system for monitoring and analyzing robot related data and displaying the data on a smart device is provided. The robot monitoring system comprises at least one robot in local communication with at least one robot controller. The at least one robot controller has local processing power for monitoring, gathering, and analyzing data related to the at least one robot. The data analysis results are formatted into a message file that is communicated to a storage system. The message file may then be retrieved by a smart device having software running thereon for displaying the results of the data analysis.

Abstract: A robot monitoring system for monitoring and analyzing robot related data and displaying the data on a smart device is provided. The robot monitoring system comprises at least one robot in local communication with at least one robot controller. The at least one robot controller has local processing power for monitoring, gathering, and analyzing data related to the at least one robot. The data analysis results are formatted into a message file that is communicated to a storage system. The message file may then be retrieved by a smart device having software running thereon for displaying the results of the data analysis.

Abstract: A conveyor system and a method for dynamically switching an active work associated with a motion device, the system including a plurality of conveyors for moving at least one part, at least one production machine associated with at least one of the conveyors, at least one motion device to move the at least one part, a controller associated with the at least one motion device, wherein the controller is in data communication with the at least one production machine to receive a feedback data therefrom, the feedback data representing a state of the production machine, and a software system executed by the controller to dynamically and selectively control the at least one motion device in response to the feedback data.

Abstract: A conveyor system and a method for dynamically switching an active work associated with a motion device, the system including a plurality of conveyors for moving at least one part, at least one production machine associated with at least one of the conveyors, at least one motion device to move the at least one part, a controller associated with the at least one motion device, wherein the controller is in data communication with the at least one production machine to receive a feedback data therefrom, the feedback data representing a state of the production machine, and a software system executed by the controller to dynamically and selectively control the at least one motion device in response to the feedback data.